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//! [<img alt="github" src="https://img.shields.io/badge/github-udoprog/relative--path-8da0cb?style=for-the-badge&logo=github" height="20">](https://github.com/udoprog/relative-path)
//! [<img alt="crates.io" src="https://img.shields.io/crates/v/relative-path.svg?style=for-the-badge&color=fc8d62&logo=rust" height="20">](https://crates.io/crates/relative-path)
//! [<img alt="docs.rs" src="https://img.shields.io/badge/docs.rs-relative--path-66c2a5?style=for-the-badge&logoColor=white&logo=data:image/svg+xml;base64,PHN2ZyByb2xlPSJpbWciIHhtbG5zPSJodHRwOi8vd3d3LnczLm9yZy8yMDAwL3N2ZyIgdmlld0JveD0iMCAwIDUxMiA1MTIiPjxwYXRoIGZpbGw9IiNmNWY1ZjUiIGQ9Ik00ODguNiAyNTAuMkwzOTIgMjE0VjEwNS41YzAtMTUtOS4zLTI4LjQtMjMuNC0zMy43bC0xMDAtMzcuNWMtOC4xLTMuMS0xNy4xLTMuMS0yNS4zIDBsLTEwMCAzNy41Yy0xNC4xIDUuMy0yMy40IDE4LjctMjMuNCAzMy43VjIxNGwtOTYuNiAzNi4yQzkuMyAyNTUuNSAwIDI2OC45IDAgMjgzLjlWMzk0YzAgMTMuNiA3LjcgMjYuMSAxOS45IDMyLjJsMTAwIDUwYzEwLjEgNS4xIDIyLjEgNS4xIDMyLjIgMGwxMDMuOS01MiAxMDMuOSA1MmMxMC4xIDUuMSAyMi4xIDUuMSAzMi4yIDBsMTAwLTUwYzEyLjItNi4xIDE5LjktMTguNiAxOS45LTMyLjJWMjgzLjljMC0xNS05LjMtMjguNC0yMy40LTMzLjd6TTM1OCAyMTQuOGwtODUgMzEuOXYtNjguMmw4NS0zN3Y3My4zek0xNTQgMTA0LjFsMTAyLTM4LjIgMTAyIDM4LjJ2LjZsLTEwMiA0MS40LTEwMi00MS40di0uNnptODQgMjkxLjFsLTg1IDQyLjV2LTc5LjFsODUtMzguOHY3NS40em0wLTExMmwtMTAyIDQxLjQtMTAyLTQxLjR2LS42bDEwMi0zOC4yIDEwMiAzOC4ydi42em0yNDAgMTEybC04NSA0Mi41di03OS4xbDg1LTM4Ljh2NzUuNHptMC0xMTJsLTEwMiA0MS40LTEwMi00MS40di0uNmwxMDItMzguMiAxMDIgMzguMnYuNnoiPjwvcGF0aD48L3N2Zz4K" height="20">](https://docs.rs/relative-path)
//!
//! Portable relative UTF-8 paths for Rust.
//!
//! This crate provides a module analogous to [`std::path`], with the following
//! characteristics:
//!
//! * The path separator is set to a fixed character (`/`), regardless of
//! platform.
//! * Relative paths cannot represent a path in the filesystem without first
//! specifying *what they are relative to* using functions such as [`to_path`]
//! and [`to_logical_path`].
//! * Relative paths are always guaranteed to be valid UTF-8 strings.
//!
//! On top of this we support many operations that guarantee the same behavior
//! across platforms.
//!
//! For more utilities to manipulate relative paths, see the
//! [`relative-path-utils` crate].
//!
//! <br>
//!
//! ## Usage
//!
//! Add `relative-path` to your `Cargo.toml`:
//!
//! ```toml
//! relative-path = "1.9.2"
//! ```
//!
//! Start using relative paths:
//!
//! ```
//! use serde::{Serialize, Deserialize};
//! use relative_path::RelativePath;
//!
//! #[derive(Serialize, Deserialize)]
//! struct Manifest<'a> {
//! #[serde(borrow)]
//! source: &'a RelativePath,
//! }
//!
//! # Ok::<_, Box<dyn std::error::Error>>(())
//! ```
//!
//! <br>
//!
//! ## Serde Support
//!
//! This library includes serde support that can be enabled with the `serde`
//! feature.
//!
//! <br>
//!
//! ## Why is `std::path` a portability hazard?
//!
//! Path representations differ across platforms.
//!
//! * Windows permits using drive volumes (multiple roots) as a prefix (e.g.
//! `"c:\"`) and backslash (`\`) as a separator.
//! * Unix references absolute paths from a single root and uses forward slash
//! (`/`) as a separator.
//!
//! If we use `PathBuf`, Storing paths in a manifest would allow our application
//! to build and run on one platform but potentially not others.
//!
//! Consider the following data model and corresponding toml for a manifest:
//!
//! ```rust
//! use std::path::PathBuf;
//!
//! use serde::{Serialize, Deserialize};
//!
//! #[derive(Serialize, Deserialize)]
//! struct Manifest {
//! source: PathBuf,
//! }
//! ```
//!
//! ```toml
//! source = "C:\\Users\\udoprog\\repo\\data\\source"
//! ```
//!
//! This will run for you (assuming `source` exists). So you go ahead and check
//! the manifest into git. The next day your Linux colleague calls you and
//! wonders what they have ever done to wrong you?
//!
//! So what went wrong? Well two things. You forgot to make the `source`
//! relative, so anyone at the company which has a different username than you
//! won't be able to use it. So you go ahead and fix that:
//!
//! ```toml
//! source = "data\\source"
//! ```
//!
//! But there is still one problem! A backslash (`\`) is only a legal path
//! separator on Windows. Luckily you learn that forward slashes are supported
//! both on Windows *and* Linux. So you opt for:
//!
//! ```toml
//! source = "data/source"
//! ```
//!
//! Things are working now. So all is well... Right? Sure, but we can do better.
//!
//! This crate provides types that work with *portable relative paths* (hence
//! the name). So by using [`RelativePath`] we can systematically help avoid
//! portability issues like the one above. Avoiding issues at the source is
//! preferably over spending 5 minutes of onboarding time on a theoretical
//! problem, hoping that your new hires will remember what to do if they ever
//! encounter it.
//!
//! Using [`RelativePathBuf`] we can fix our data model like this:
//!
//! ```rust
//! use relative_path::RelativePathBuf;
//! use serde::{Serialize, Deserialize};
//!
//! #[derive(Serialize, Deserialize)]
//! pub struct Manifest {
//! source: RelativePathBuf,
//! }
//! ```
//!
//! And where it's used:
//!
//! ```rust,no_run
//! # use relative_path::RelativePathBuf;
//! # use serde::{Serialize, Deserialize};
//! # #[derive(Serialize, Deserialize)] pub struct Manifest { source: RelativePathBuf }
//! use std::fs;
//! use std::env::current_dir;
//!
//! let manifest: Manifest = todo!();
//!
//! let root = current_dir()?;
//! let source = manifest.source.to_path(&root);
//! let content = fs::read(&source)?;
//! # Ok::<_, Box<dyn std::error::Error>>(())
//! ```
//!
//! <br>
//!
//! ## Overview
//!
//! Conversion to a platform-specific [`Path`] happens through the [`to_path`]
//! and [`to_logical_path`] functions. Where you are required to specify the
//! path that prefixes the relative path. This can come from a function such as
//! [`std::env::current_dir`].
//!
//! ```rust
//! use std::env::current_dir;
//! use std::path::Path;
//!
//! use relative_path::RelativePath;
//!
//! let root = current_dir()?;
//!
//! # if cfg!(windows) {
//! // to_path unconditionally concatenates a relative path with its base:
//! let relative_path = RelativePath::new("../foo/./bar");
//! let full_path = relative_path.to_path(&root);
//! assert_eq!(full_path, root.join("..\\foo\\.\\bar"));
//!
//! // to_logical_path tries to apply the logical operations that the relative
//! // path corresponds to:
//! let relative_path = RelativePath::new("../foo/./bar");
//! let full_path = relative_path.to_logical_path(&root);
//!
//! // Replicate the operation performed by `to_logical_path`.
//! let mut parent = root.clone();
//! parent.pop();
//! assert_eq!(full_path, parent.join("foo\\bar"));
//! # }
//! # Ok::<_, std::io::Error>(())
//! ```
//!
//! When two relative paths are compared to each other, their exact component
//! makeup determines equality.
//!
//! ```rust
//! use relative_path::RelativePath;
//!
//! assert_ne!(
//! RelativePath::new("foo/bar/../baz"),
//! RelativePath::new("foo/baz")
//! );
//! ```
//!
//! Using platform-specific path separators to construct relative paths is not
//! supported.
//!
//! Path separators from other platforms are simply treated as part of a
//! component:
//!
//! ```rust
//! use relative_path::RelativePath;
//!
//! assert_ne!(
//! RelativePath::new("foo/bar"),
//! RelativePath::new("foo\\bar")
//! );
//!
//! assert_eq!(1, RelativePath::new("foo\\bar").components().count());
//! assert_eq!(2, RelativePath::new("foo/bar").components().count());
//! ```
//!
//! To see if two relative paths are equivalent you can use [`normalize`]:
//!
//! ```rust
//! use relative_path::RelativePath;
//!
//! assert_eq!(
//! RelativePath::new("foo/bar/../baz").normalize(),
//! RelativePath::new("foo/baz").normalize(),
//! );
//! ```
//!
//! <br>
//!
//! ## Additional portability notes
//!
//! While relative paths avoid the most egregious portability issue, that
//! absolute paths will work equally unwell on all platforms. We cannot avoid
//! all. This section tries to document additional portability hazards that we
//! are aware of.
//!
//! [`RelativePath`], similarly to [`Path`], makes no guarantees that its
//! constituent components make up legal file names. While components are
//! strictly separated by slashes, we can still store things in them which may
//! not be used as legal paths on all platforms.
//!
//! * A `NUL` character is not permitted on unix platforms - this is a
//! terminator in C-based filesystem APIs. Slash (`/`) is also used as a path
//! separator.
//! * Windows has a number of [reserved characters and names][windows-reserved]
//! (like `CON`, `PRN`, and `AUX`) which cannot legally be part of a
//! filesystem component.
//! * Windows paths are [case-insensitive by default][windows-case]. So,
//! `Foo.txt` and `foo.txt` are the same files on windows. But they are
//! considered different paths on most unix systems.
//!
//! A relative path that *accidentally* contains a platform-specific components
//! will largely result in a nonsensical paths being generated in the hope that
//! they will fail fast during development and testing.
//!
//! ```rust
//! use relative_path::{RelativePath, PathExt};
//! use std::path::Path;
//!
//! if cfg!(windows) {
//! assert_eq!(
//! Path::new("foo\\c:\\bar\\baz"),
//! RelativePath::new("c:\\bar\\baz").to_path("foo")
//! );
//! }
//!
//! if cfg!(unix) {
//! assert_eq!(
//! Path::new("foo/bar/baz"),
//! RelativePath::new("/bar/baz").to_path("foo")
//! );
//! }
//!
//! assert_eq!(
//! Path::new("foo").relative_to("bar")?,
//! RelativePath::new("../foo"),
//! );
//! # Ok::<_, Box<dyn std::error::Error>>(())
//! ```
//!
//! [`None`]: https://doc.rust-lang.org/std/option/enum.Option.html
//! [`normalize`]: https://docs.rs/relative-path/1/relative_path/struct.RelativePath.html#method.normalize
//! [`Path`]: https://doc.rust-lang.org/std/path/struct.Path.html
//! [`RelativePath`]: https://docs.rs/relative-path/1/relative_path/struct.RelativePath.html
//! [`RelativePathBuf`]: https://docs.rs/relative-path/1/relative_path/struct.RelativePathBuf.html
//! [`std::env::current_dir`]: https://doc.rust-lang.org/std/env/fn.current_dir.html
//! [`std::path`]: https://doc.rust-lang.org/std/path/index.html
//! [`to_logical_path`]: https://docs.rs/relative-path/1/relative_path/struct.RelativePath.html#method.to_logical_path
//! [`to_path`]: https://docs.rs/relative-path/1/relative_path/struct.RelativePath.html#method.to_path
//! [windows-reserved]: https://msdn.microsoft.com/en-us/library/windows/desktop/aa365247(v=vs.85).aspx
//! [windows-case]: https://learn.microsoft.com/en-us/windows/wsl/case-sensitivity
//! [`relative-path-utils` crate]: https://docs.rs/relative-path-utils
// This file contains parts that are Copyright 2015 The Rust Project Developers, copied from:
// https://github.com/rust-lang/rust
// cb2a656cdfb6400ac0200c661267f91fabf237e2 src/libstd/path.rs
#![allow(clippy::manual_let_else)]
#![deny(missing_docs)]
mod path_ext;
#[cfg(test)]
mod tests;
pub use path_ext::{PathExt, RelativeToError};
use std::borrow::{Borrow, Cow};
use std::cmp;
use std::error;
use std::fmt;
use std::hash::{Hash, Hasher};
use std::iter::FromIterator;
use std::mem;
use std::ops;
use std::path;
use std::rc::Rc;
use std::str;
use std::sync::Arc;
const STEM_SEP: char = '.';
const CURRENT_STR: &str = ".";
const PARENT_STR: &str = "..";
const SEP: char = '/';
fn split_file_at_dot(input: &str) -> (Option<&str>, Option<&str>) {
if input == PARENT_STR {
return (Some(input), None);
}
let mut iter = input.rsplitn(2, STEM_SEP);
let after = iter.next();
let before = iter.next();
if before == Some("") {
(Some(input), None)
} else {
(before, after)
}
}
// Iterate through `iter` while it matches `prefix`; return `None` if `prefix`
// is not a prefix of `iter`, otherwise return `Some(iter_after_prefix)` giving
// `iter` after having exhausted `prefix`.
fn iter_after<'a, 'b, I, J>(mut iter: I, mut prefix: J) -> Option<I>
where
I: Iterator<Item = Component<'a>> + Clone,
J: Iterator<Item = Component<'b>>,
{
loop {
let mut iter_next = iter.clone();
match (iter_next.next(), prefix.next()) {
(Some(x), Some(y)) if x == y => (),
(Some(_) | None, Some(_)) => return None,
(Some(_) | None, None) => return Some(iter),
}
iter = iter_next;
}
}
/// A single path component.
///
/// Accessed using the [`RelativePath::components`] iterator.
///
/// # Examples
///
/// ```
/// use relative_path::{Component, RelativePath};
///
/// let path = RelativePath::new("foo/../bar/./baz");
/// let mut it = path.components();
///
/// assert_eq!(Some(Component::Normal("foo")), it.next());
/// assert_eq!(Some(Component::ParentDir), it.next());
/// assert_eq!(Some(Component::Normal("bar")), it.next());
/// assert_eq!(Some(Component::CurDir), it.next());
/// assert_eq!(Some(Component::Normal("baz")), it.next());
/// assert_eq!(None, it.next());
/// ```
#[derive(Copy, Clone, Debug, Hash, PartialEq, Eq, PartialOrd, Ord)]
pub enum Component<'a> {
/// The current directory `.`.
CurDir,
/// The parent directory `..`.
ParentDir,
/// A normal path component as a string.
Normal(&'a str),
}
impl<'a> Component<'a> {
/// Extracts the underlying [`str`] slice.
///
/// [`str`]: prim@str
///
/// # Examples
///
/// ```
/// use relative_path::{RelativePath, Component};
///
/// let path = RelativePath::new("./tmp/../foo/bar.txt");
/// let components: Vec<_> = path.components().map(Component::as_str).collect();
/// assert_eq!(&components, &[".", "tmp", "..", "foo", "bar.txt"]);
/// ```
#[must_use]
pub fn as_str(self) -> &'a str {
use self::Component::{CurDir, Normal, ParentDir};
match self {
CurDir => CURRENT_STR,
ParentDir => PARENT_STR,
Normal(name) => name,
}
}
}
/// [`AsRef<RelativePath>`] implementation for [`Component`].
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let mut it = RelativePath::new("../foo/bar").components();
///
/// let a = it.next().ok_or("a")?;
/// let b = it.next().ok_or("b")?;
/// let c = it.next().ok_or("c")?;
///
/// let a: &RelativePath = a.as_ref();
/// let b: &RelativePath = b.as_ref();
/// let c: &RelativePath = c.as_ref();
///
/// assert_eq!(a, "..");
/// assert_eq!(b, "foo");
/// assert_eq!(c, "bar");
///
/// # Ok::<_, Box<dyn std::error::Error>>(())
/// ```
impl AsRef<RelativePath> for Component<'_> {
#[inline]
fn as_ref(&self) -> &RelativePath {
self.as_str().as_ref()
}
}
/// Traverse the given components and apply to the provided stack.
///
/// This takes '.', and '..' into account. Where '.' doesn't change the stack, and '..' pops the
/// last item or further adds parent components.
#[inline(always)]
fn relative_traversal<'a, C>(buf: &mut RelativePathBuf, components: C)
where
C: IntoIterator<Item = Component<'a>>,
{
use self::Component::{CurDir, Normal, ParentDir};
for c in components {
match c {
CurDir => (),
ParentDir => match buf.components().next_back() {
Some(Component::ParentDir) | None => {
buf.push(PARENT_STR);
}
_ => {
buf.pop();
}
},
Normal(name) => {
buf.push(name);
}
}
}
}
/// Iterator over all the components in a relative path.
#[derive(Clone)]
pub struct Components<'a> {
source: &'a str,
}
impl<'a> Iterator for Components<'a> {
type Item = Component<'a>;
fn next(&mut self) -> Option<Self::Item> {
self.source = self.source.trim_start_matches(SEP);
let slice = match self.source.find(SEP) {
Some(i) => {
let (slice, rest) = self.source.split_at(i);
self.source = rest.trim_start_matches(SEP);
slice
}
None => mem::take(&mut self.source),
};
match slice {
"" => None,
CURRENT_STR => Some(Component::CurDir),
PARENT_STR => Some(Component::ParentDir),
slice => Some(Component::Normal(slice)),
}
}
}
impl<'a> DoubleEndedIterator for Components<'a> {
fn next_back(&mut self) -> Option<Self::Item> {
self.source = self.source.trim_end_matches(SEP);
let slice = match self.source.rfind(SEP) {
Some(i) => {
let (rest, slice) = self.source.split_at(i + 1);
self.source = rest.trim_end_matches(SEP);
slice
}
None => mem::take(&mut self.source),
};
match slice {
"" => None,
CURRENT_STR => Some(Component::CurDir),
PARENT_STR => Some(Component::ParentDir),
slice => Some(Component::Normal(slice)),
}
}
}
impl<'a> Components<'a> {
/// Construct a new component from the given string.
fn new(source: &'a str) -> Components<'a> {
Self { source }
}
/// Extracts a slice corresponding to the portion of the path remaining for iteration.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let mut components = RelativePath::new("tmp/foo/bar.txt").components();
/// components.next();
/// components.next();
///
/// assert_eq!("bar.txt", components.as_relative_path());
/// ```
#[must_use]
#[inline]
pub fn as_relative_path(&self) -> &'a RelativePath {
RelativePath::new(self.source)
}
}
impl<'a> cmp::PartialEq for Components<'a> {
fn eq(&self, other: &Components<'a>) -> bool {
Iterator::eq(self.clone(), other.clone())
}
}
/// An iterator over the [`Component`]s of a [`RelativePath`], as [`str`]
/// slices.
///
/// This `struct` is created by the [`iter`][RelativePath::iter] method.
///
/// [`str`]: prim@str
#[derive(Clone)]
pub struct Iter<'a> {
inner: Components<'a>,
}
impl<'a> Iterator for Iter<'a> {
type Item = &'a str;
fn next(&mut self) -> Option<&'a str> {
self.inner.next().map(Component::as_str)
}
}
impl<'a> DoubleEndedIterator for Iter<'a> {
fn next_back(&mut self) -> Option<&'a str> {
self.inner.next_back().map(Component::as_str)
}
}
/// Error kind for [`FromPathError`].
#[derive(Debug, Clone, Copy, PartialEq, Eq)]
#[non_exhaustive]
pub enum FromPathErrorKind {
/// Non-relative component in path.
NonRelative,
/// Non-utf8 component in path.
NonUtf8,
/// Trying to convert a platform-specific path which uses a platform-specific separator.
BadSeparator,
}
/// An error raised when attempting to convert a path using
/// [`RelativePathBuf::from_path`].
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct FromPathError {
kind: FromPathErrorKind,
}
impl FromPathError {
/// Gets the underlying [`FromPathErrorKind`] that provides more details on
/// what went wrong.
///
/// # Examples
///
/// ```
/// use std::path::Path;
/// use relative_path::{FromPathErrorKind, RelativePathBuf};
///
/// let result = RelativePathBuf::from_path(Path::new("/hello/world"));
/// let e = result.unwrap_err();
///
/// assert_eq!(FromPathErrorKind::NonRelative, e.kind());
/// ```
#[must_use]
pub fn kind(&self) -> FromPathErrorKind {
self.kind
}
}
impl From<FromPathErrorKind> for FromPathError {
fn from(value: FromPathErrorKind) -> Self {
Self { kind: value }
}
}
impl fmt::Display for FromPathError {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
match self.kind {
FromPathErrorKind::NonRelative => "path contains non-relative component".fmt(fmt),
FromPathErrorKind::NonUtf8 => "path contains non-utf8 component".fmt(fmt),
FromPathErrorKind::BadSeparator => {
"path contains platform-specific path separator".fmt(fmt)
}
}
}
}
impl error::Error for FromPathError {}
/// An owned, mutable relative path.
///
/// This type provides methods to manipulate relative path objects.
#[derive(Clone)]
pub struct RelativePathBuf {
inner: String,
}
impl RelativePathBuf {
/// Create a new relative path buffer.
#[must_use]
pub fn new() -> RelativePathBuf {
RelativePathBuf {
inner: String::new(),
}
}
/// Internal constructor to allocate a relative path buf with the given capacity.
fn with_capacity(cap: usize) -> RelativePathBuf {
RelativePathBuf {
inner: String::with_capacity(cap),
}
}
/// Try to convert a [`Path`] to a [`RelativePathBuf`].
///
/// [`Path`]: https://doc.rust-lang.org/std/path/struct.Path.html
///
/// # Examples
///
/// ```
/// use relative_path::{RelativePath, RelativePathBuf, FromPathErrorKind};
/// use std::path::Path;
///
/// assert_eq!(
/// Ok(RelativePath::new("foo/bar").to_owned()),
/// RelativePathBuf::from_path(Path::new("foo/bar"))
/// );
/// ```
///
/// # Errors
///
/// This will error in case the provided path is not a relative path, which
/// is identifier by it having a [`Prefix`] or [`RootDir`] component.
///
/// [`Prefix`]: std::path::Component::Prefix
/// [`RootDir`]: std::path::Component::RootDir
pub fn from_path<P: AsRef<path::Path>>(path: P) -> Result<RelativePathBuf, FromPathError> {
use std::path::Component::{CurDir, Normal, ParentDir, Prefix, RootDir};
let mut buffer = RelativePathBuf::new();
for c in path.as_ref().components() {
match c {
Prefix(_) | RootDir => return Err(FromPathErrorKind::NonRelative.into()),
CurDir => continue,
ParentDir => buffer.push(PARENT_STR),
Normal(s) => buffer.push(s.to_str().ok_or(FromPathErrorKind::NonUtf8)?),
}
}
Ok(buffer)
}
/// Extends `self` with `path`.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePathBuf;
///
/// let mut path = RelativePathBuf::new();
/// path.push("foo");
/// path.push("bar");
///
/// assert_eq!("foo/bar", path);
///
/// let mut path = RelativePathBuf::new();
/// path.push("foo");
/// path.push("/bar");
///
/// assert_eq!("foo/bar", path);
/// ```
pub fn push<P>(&mut self, path: P)
where
P: AsRef<RelativePath>,
{
let other = path.as_ref();
let other = if other.starts_with_sep() {
&other.inner[1..]
} else {
&other.inner[..]
};
if !self.inner.is_empty() && !self.ends_with_sep() {
self.inner.push(SEP);
}
self.inner.push_str(other);
}
/// Updates [`file_name`] to `file_name`.
///
/// If [`file_name`] was [`None`], this is equivalent to pushing
/// `file_name`.
///
/// Otherwise it is equivalent to calling [`pop`] and then pushing
/// `file_name`. The new path will be a sibling of the original path. (That
/// is, it will have the same parent.)
///
/// [`file_name`]: RelativePath::file_name
/// [`pop`]: RelativePathBuf::pop
/// [`None`]: https://doc.rust-lang.org/std/option/enum.Option.html
///
/// # Examples
///
/// ```
/// use relative_path::RelativePathBuf;
///
/// let mut buf = RelativePathBuf::from("");
/// assert!(buf.file_name() == None);
/// buf.set_file_name("bar");
/// assert_eq!(RelativePathBuf::from("bar"), buf);
///
/// assert!(buf.file_name().is_some());
/// buf.set_file_name("baz.txt");
/// assert_eq!(RelativePathBuf::from("baz.txt"), buf);
///
/// buf.push("bar");
/// assert!(buf.file_name().is_some());
/// buf.set_file_name("bar.txt");
/// assert_eq!(RelativePathBuf::from("baz.txt/bar.txt"), buf);
/// ```
pub fn set_file_name<S: AsRef<str>>(&mut self, file_name: S) {
if self.file_name().is_some() {
let popped = self.pop();
debug_assert!(popped);
}
self.push(file_name.as_ref());
}
/// Updates [`extension`] to `extension`.
///
/// Returns `false` and does nothing if
/// [`file_name`][RelativePath::file_name] is [`None`], returns `true` and
/// updates the extension otherwise.
///
/// If [`extension`] is [`None`], the extension is added; otherwise it is
/// replaced.
///
/// [`extension`]: RelativePath::extension
///
/// # Examples
///
/// ```
/// use relative_path::{RelativePath, RelativePathBuf};
///
/// let mut p = RelativePathBuf::from("feel/the");
///
/// p.set_extension("force");
/// assert_eq!(RelativePath::new("feel/the.force"), p);
///
/// p.set_extension("dark_side");
/// assert_eq!(RelativePath::new("feel/the.dark_side"), p);
///
/// assert!(p.pop());
/// p.set_extension("nothing");
/// assert_eq!(RelativePath::new("feel.nothing"), p);
/// ```
pub fn set_extension<S: AsRef<str>>(&mut self, extension: S) -> bool {
let file_stem = match self.file_stem() {
Some(stem) => stem,
None => return false,
};
let end_file_stem = file_stem[file_stem.len()..].as_ptr() as usize;
let start = self.inner.as_ptr() as usize;
self.inner.truncate(end_file_stem.wrapping_sub(start));
let extension = extension.as_ref();
if !extension.is_empty() {
self.inner.push(STEM_SEP);
self.inner.push_str(extension);
}
true
}
/// Truncates `self` to [`parent`][RelativePath::parent].
///
/// # Examples
///
/// ```
/// use relative_path::{RelativePath, RelativePathBuf};
///
/// let mut p = RelativePathBuf::from("test/test.rs");
///
/// assert_eq!(true, p.pop());
/// assert_eq!(RelativePath::new("test"), p);
/// assert_eq!(true, p.pop());
/// assert_eq!(RelativePath::new(""), p);
/// assert_eq!(false, p.pop());
/// assert_eq!(RelativePath::new(""), p);
/// ```
pub fn pop(&mut self) -> bool {
match self.parent().map(|p| p.inner.len()) {
Some(len) => {
self.inner.truncate(len);
true
}
None => false,
}
}
/// Coerce to a [`RelativePath`] slice.
#[must_use]
pub fn as_relative_path(&self) -> &RelativePath {
self
}
/// Consumes the `RelativePathBuf`, yielding its internal [`String`] storage.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePathBuf;
///
/// let p = RelativePathBuf::from("/the/head");
/// let string = p.into_string();
/// assert_eq!(string, "/the/head".to_owned());
/// ```
#[must_use]
pub fn into_string(self) -> String {
self.inner
}
/// Converts this `RelativePathBuf` into a [boxed][std::boxed::Box]
/// [`RelativePath`].
#[must_use]
pub fn into_boxed_relative_path(self) -> Box<RelativePath> {
let rw = Box::into_raw(self.inner.into_boxed_str()) as *mut RelativePath;
unsafe { Box::from_raw(rw) }
}
}
impl Default for RelativePathBuf {
fn default() -> Self {
RelativePathBuf::new()
}
}
impl<'a> From<&'a RelativePath> for Cow<'a, RelativePath> {
#[inline]
fn from(s: &'a RelativePath) -> Cow<'a, RelativePath> {
Cow::Borrowed(s)
}
}
impl<'a> From<RelativePathBuf> for Cow<'a, RelativePath> {
#[inline]
fn from(s: RelativePathBuf) -> Cow<'a, RelativePath> {
Cow::Owned(s)
}
}
impl fmt::Debug for RelativePathBuf {
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
write!(fmt, "{:?}", &self.inner)
}
}
impl AsRef<RelativePath> for RelativePathBuf {
fn as_ref(&self) -> &RelativePath {
RelativePath::new(&self.inner)
}
}
impl AsRef<str> for RelativePath {
fn as_ref(&self) -> &str {
&self.inner
}
}
impl Borrow<RelativePath> for RelativePathBuf {
#[inline]
fn borrow(&self) -> &RelativePath {
self
}
}
impl<'a, T: ?Sized + AsRef<str>> From<&'a T> for RelativePathBuf {
fn from(path: &'a T) -> RelativePathBuf {
RelativePathBuf {
inner: path.as_ref().to_owned(),
}
}
}
impl From<String> for RelativePathBuf {
fn from(path: String) -> RelativePathBuf {
RelativePathBuf { inner: path }
}
}
impl From<RelativePathBuf> for String {
fn from(path: RelativePathBuf) -> String {
path.into_string()
}
}
impl ops::Deref for RelativePathBuf {
type Target = RelativePath;
fn deref(&self) -> &RelativePath {
RelativePath::new(&self.inner)
}
}
impl cmp::PartialEq for RelativePathBuf {
fn eq(&self, other: &RelativePathBuf) -> bool {
self.components() == other.components()
}
}
impl cmp::Eq for RelativePathBuf {}
impl cmp::PartialOrd for RelativePathBuf {
#[inline]
fn partial_cmp(&self, other: &RelativePathBuf) -> Option<cmp::Ordering> {
Some(self.cmp(other))
}
}
impl cmp::Ord for RelativePathBuf {
#[inline]
fn cmp(&self, other: &RelativePathBuf) -> cmp::Ordering {
self.components().cmp(other.components())
}
}
impl Hash for RelativePathBuf {
fn hash<H: Hasher>(&self, h: &mut H) {
self.as_relative_path().hash(h);
}
}
impl<P> Extend<P> for RelativePathBuf
where
P: AsRef<RelativePath>,
{
#[inline]
fn extend<I: IntoIterator<Item = P>>(&mut self, iter: I) {
iter.into_iter().for_each(move |p| self.push(p.as_ref()));
}
}
impl<P> FromIterator<P> for RelativePathBuf
where
P: AsRef<RelativePath>,
{
#[inline]
fn from_iter<I: IntoIterator<Item = P>>(iter: I) -> RelativePathBuf {
let mut buf = RelativePathBuf::new();
buf.extend(iter);
buf
}
}
/// A borrowed, immutable relative path.
#[repr(transparent)]
pub struct RelativePath {
inner: str,
}
/// An error returned from [`strip_prefix`] if the prefix was not found.
///
/// [`strip_prefix`]: RelativePath::strip_prefix
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct StripPrefixError(());
impl RelativePath {
/// Directly wraps a string slice as a `RelativePath` slice.
pub fn new<S: AsRef<str> + ?Sized>(s: &S) -> &RelativePath {
unsafe { &*(s.as_ref() as *const str as *const RelativePath) }
}
/// Try to convert a [`Path`] to a [`RelativePath`] without allocating a buffer.
///
/// [`Path`]: std::path::Path
///
/// # Errors
///
/// This requires the path to be a legal, platform-neutral relative path.
/// Otherwise various forms of [`FromPathError`] will be returned as an
/// [`Err`].
///
/// # Examples
///
/// ```
/// use relative_path::{RelativePath, FromPathErrorKind};
///
/// assert_eq!(
/// Ok(RelativePath::new("foo/bar")),
/// RelativePath::from_path("foo/bar")
/// );
///
/// // Note: absolute paths are different depending on platform.
/// if cfg!(windows) {
/// let e = RelativePath::from_path("c:\\foo\\bar").unwrap_err();
/// assert_eq!(FromPathErrorKind::NonRelative, e.kind());
/// }
///
/// if cfg!(unix) {
/// let e = RelativePath::from_path("/foo/bar").unwrap_err();
/// assert_eq!(FromPathErrorKind::NonRelative, e.kind());
/// }
/// ```
pub fn from_path<P: ?Sized + AsRef<path::Path>>(
path: &P,
) -> Result<&RelativePath, FromPathError> {
use std::path::Component::{CurDir, Normal, ParentDir, Prefix, RootDir};
let other = path.as_ref();
let s = match other.to_str() {
Some(s) => s,
None => return Err(FromPathErrorKind::NonUtf8.into()),
};
let rel = RelativePath::new(s);
// check that the component compositions are equal.
for (a, b) in other.components().zip(rel.components()) {
match (a, b) {
(Prefix(_) | RootDir, _) => return Err(FromPathErrorKind::NonRelative.into()),
(CurDir, Component::CurDir) | (ParentDir, Component::ParentDir) => continue,
(Normal(a), Component::Normal(b)) if a == b => continue,
_ => return Err(FromPathErrorKind::BadSeparator.into()),
}
}
Ok(rel)
}
/// Yields the underlying [`str`] slice.
///
/// [`str`]: prim@str
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// assert_eq!(RelativePath::new("foo.txt").as_str(), "foo.txt");
/// ```
#[must_use]
pub fn as_str(&self) -> &str {
&self.inner
}
/// Returns an object that implements [`Display`][std::fmt::Display].
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path = RelativePath::new("tmp/foo.rs");
///
/// println!("{}", path.display());
/// ```
#[deprecated(note = "RelativePath implements std::fmt::Display directly")]
#[must_use]
pub fn display(&self) -> Display {
Display { path: self }
}
/// Creates an owned [`RelativePathBuf`] with path adjoined to self.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path = RelativePath::new("foo/bar");
/// assert_eq!("foo/bar/baz", path.join("baz"));
/// ```
pub fn join<P>(&self, path: P) -> RelativePathBuf
where
P: AsRef<RelativePath>,
{
let mut out = self.to_relative_path_buf();
out.push(path);
out
}
/// Iterate over all components in this relative path.
///
/// # Examples
///
/// ```
/// use relative_path::{Component, RelativePath};
///
/// let path = RelativePath::new("foo/bar/baz");
/// let mut it = path.components();
///
/// assert_eq!(Some(Component::Normal("foo")), it.next());
/// assert_eq!(Some(Component::Normal("bar")), it.next());
/// assert_eq!(Some(Component::Normal("baz")), it.next());
/// assert_eq!(None, it.next());
/// ```
#[must_use]
pub fn components(&self) -> Components {
Components::new(&self.inner)
}
/// Produces an iterator over the path's components viewed as [`str`]
/// slices.
///
/// For more information about the particulars of how the path is separated
/// into components, see [`components`][Self::components].
///
/// [`str`]: prim@str
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let mut it = RelativePath::new("/tmp/foo.txt").iter();
/// assert_eq!(it.next(), Some("tmp"));
/// assert_eq!(it.next(), Some("foo.txt"));
/// assert_eq!(it.next(), None)
/// ```
#[must_use]
pub fn iter(&self) -> Iter {
Iter {
inner: self.components(),
}
}
/// Convert to an owned [`RelativePathBuf`].
#[must_use]
pub fn to_relative_path_buf(&self) -> RelativePathBuf {
RelativePathBuf::from(self.inner.to_owned())
}
/// Build an owned [`PathBuf`] relative to `base` for the current relative
/// path.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
/// use std::path::Path;
///
/// let path = RelativePath::new("foo/bar").to_path(".");
/// assert_eq!(Path::new("./foo/bar"), path);
///
/// let path = RelativePath::new("foo/bar").to_path("");
/// assert_eq!(Path::new("foo/bar"), path);
/// ```
///
/// # Encoding an absolute path
///
/// Absolute paths are, in contrast to when using [`PathBuf::push`] *ignored*
/// and will be added unchanged to the buffer.
///
/// This is to preserve the probability of a path conversion failing if the
/// relative path contains platform-specific absolute path components.
///
/// ```
/// use relative_path::RelativePath;
/// use std::path::Path;
///
/// if cfg!(windows) {
/// let path = RelativePath::new("/bar/baz").to_path("foo");
/// assert_eq!(Path::new("foo\\bar\\baz"), path);
///
/// let path = RelativePath::new("c:\\bar\\baz").to_path("foo");
/// assert_eq!(Path::new("foo\\c:\\bar\\baz"), path);
/// }
///
/// if cfg!(unix) {
/// let path = RelativePath::new("/bar/baz").to_path("foo");
/// assert_eq!(Path::new("foo/bar/baz"), path);
///
/// let path = RelativePath::new("c:\\bar\\baz").to_path("foo");
/// assert_eq!(Path::new("foo/c:\\bar\\baz"), path);
/// }
/// ```
///
/// [`PathBuf`]: std::path::PathBuf
/// [`PathBuf::push`]: std::path::PathBuf::push
pub fn to_path<P: AsRef<path::Path>>(&self, base: P) -> path::PathBuf {
let mut p = base.as_ref().to_path_buf().into_os_string();
for c in self.components() {
if !p.is_empty() {
p.push(path::MAIN_SEPARATOR.encode_utf8(&mut [0u8, 0u8, 0u8, 0u8]));
}
p.push(c.as_str());
}
path::PathBuf::from(p)
}
/// Build an owned [`PathBuf`] relative to `base` for the current relative
/// path.
///
/// This is similar to [`to_path`] except that it doesn't just
/// unconditionally append one path to the other, instead it performs the
/// following operations depending on its own components:
///
/// * [`Component::CurDir`] leaves the `base` unmodified.
/// * [`Component::ParentDir`] removes a component from `base` using
/// [`path::PathBuf::pop`].
/// * [`Component::Normal`] pushes the given path component onto `base`
/// using the same mechanism as [`to_path`].
///
/// [`to_path`]: RelativePath::to_path
///
/// Note that the exact semantics of the path operation is determined by the
/// corresponding [`PathBuf`] operation. E.g. popping a component off a path
/// like `.` will result in an empty path.
///
/// ```
/// use relative_path::RelativePath;
/// use std::path::Path;
///
/// let path = RelativePath::new("..").to_logical_path(".");
/// assert_eq!(path, Path::new(""));
/// ```
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
/// use std::path::Path;
///
/// let path = RelativePath::new("..").to_logical_path("foo/bar");
/// assert_eq!(path, Path::new("foo"));
/// ```
///
/// # Encoding an absolute path
///
/// Behaves the same as [`to_path`][RelativePath::to_path] when encoding
/// absolute paths.
///
/// Absolute paths are, in contrast to when using [`PathBuf::push`] *ignored*
/// and will be added unchanged to the buffer.
///
/// This is to preserve the probability of a path conversion failing if the
/// relative path contains platform-specific absolute path components.
///
/// ```
/// use relative_path::RelativePath;
/// use std::path::Path;
///
/// if cfg!(windows) {
/// let path = RelativePath::new("/bar/baz").to_logical_path("foo");
/// assert_eq!(Path::new("foo\\bar\\baz"), path);
///
/// let path = RelativePath::new("c:\\bar\\baz").to_logical_path("foo");
/// assert_eq!(Path::new("foo\\c:\\bar\\baz"), path);
///
/// let path = RelativePath::new("foo/bar").to_logical_path("");
/// assert_eq!(Path::new("foo\\bar"), path);
/// }
///
/// if cfg!(unix) {
/// let path = RelativePath::new("/bar/baz").to_logical_path("foo");
/// assert_eq!(Path::new("foo/bar/baz"), path);
///
/// let path = RelativePath::new("c:\\bar\\baz").to_logical_path("foo");
/// assert_eq!(Path::new("foo/c:\\bar\\baz"), path);
///
/// let path = RelativePath::new("foo/bar").to_logical_path("");
/// assert_eq!(Path::new("foo/bar"), path);
/// }
/// ```
///
/// [`PathBuf`]: std::path::PathBuf
/// [`PathBuf::push`]: std::path::PathBuf::push
pub fn to_logical_path<P: AsRef<path::Path>>(&self, base: P) -> path::PathBuf {
use self::Component::{CurDir, Normal, ParentDir};
let mut p = base.as_ref().to_path_buf().into_os_string();
for c in self.components() {
match c {
CurDir => continue,
ParentDir => {
let mut temp = path::PathBuf::from(std::mem::take(&mut p));
temp.pop();
p = temp.into_os_string();
}
Normal(c) => {
if !p.is_empty() {
p.push(path::MAIN_SEPARATOR.encode_utf8(&mut [0u8, 0u8, 0u8, 0u8]));
}
p.push(c);
}
}
}
path::PathBuf::from(p)
}
/// Returns a relative path, without its final [`Component`] if there is one.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// assert_eq!(Some(RelativePath::new("foo")), RelativePath::new("foo/bar").parent());
/// assert_eq!(Some(RelativePath::new("")), RelativePath::new("foo").parent());
/// assert_eq!(None, RelativePath::new("").parent());
/// ```
#[must_use]
pub fn parent(&self) -> Option<&RelativePath> {
use self::Component::CurDir;
if self.inner.is_empty() {
return None;
}
let mut it = self.components();
while let Some(CurDir) = it.next_back() {}
Some(it.as_relative_path())
}
/// Returns the final component of the `RelativePath`, if there is one.
///
/// If the path is a normal file, this is the file name. If it's the path of
/// a directory, this is the directory name.
///
/// Returns [`None`] If the path terminates in `..`.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// assert_eq!(Some("bin"), RelativePath::new("usr/bin/").file_name());
/// assert_eq!(Some("foo.txt"), RelativePath::new("tmp/foo.txt").file_name());
/// assert_eq!(Some("foo.txt"), RelativePath::new("tmp/foo.txt/").file_name());
/// assert_eq!(Some("foo.txt"), RelativePath::new("foo.txt/.").file_name());
/// assert_eq!(Some("foo.txt"), RelativePath::new("foo.txt/.//").file_name());
/// assert_eq!(None, RelativePath::new("foo.txt/..").file_name());
/// assert_eq!(None, RelativePath::new("/").file_name());
/// ```
#[must_use]
pub fn file_name(&self) -> Option<&str> {
use self::Component::{CurDir, Normal, ParentDir};
let mut it = self.components();
while let Some(c) = it.next_back() {
return match c {
CurDir => continue,
Normal(name) => Some(name),
ParentDir => None,
};
}
None
}
/// Returns a relative path that, when joined onto `base`, yields `self`.
///
/// # Errors
///
/// If `base` is not a prefix of `self` (i.e. [`starts_with`] returns
/// `false`), returns [`Err`].
///
/// [`starts_with`]: Self::starts_with
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path = RelativePath::new("test/haha/foo.txt");
///
/// assert_eq!(path.strip_prefix("test"), Ok(RelativePath::new("haha/foo.txt")));
/// assert_eq!(path.strip_prefix("test").is_ok(), true);
/// assert_eq!(path.strip_prefix("haha").is_ok(), false);
/// ```
pub fn strip_prefix<P>(&self, base: P) -> Result<&RelativePath, StripPrefixError>
where
P: AsRef<RelativePath>,
{
iter_after(self.components(), base.as_ref().components())
.map(|c| c.as_relative_path())
.ok_or(StripPrefixError(()))
}
/// Determines whether `base` is a prefix of `self`.
///
/// Only considers whole path components to match.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path = RelativePath::new("etc/passwd");
///
/// assert!(path.starts_with("etc"));
///
/// assert!(!path.starts_with("e"));
/// ```
pub fn starts_with<P>(&self, base: P) -> bool
where
P: AsRef<RelativePath>,
{
iter_after(self.components(), base.as_ref().components()).is_some()
}
/// Determines whether `child` is a suffix of `self`.
///
/// Only considers whole path components to match.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path = RelativePath::new("etc/passwd");
///
/// assert!(path.ends_with("passwd"));
/// ```
pub fn ends_with<P>(&self, child: P) -> bool
where
P: AsRef<RelativePath>,
{
iter_after(self.components().rev(), child.as_ref().components().rev()).is_some()
}
/// Determines whether `self` is normalized.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// // These are normalized.
/// assert!(RelativePath::new("").is_normalized());
/// assert!(RelativePath::new("baz.txt").is_normalized());
/// assert!(RelativePath::new("foo/bar/baz.txt").is_normalized());
/// assert!(RelativePath::new("..").is_normalized());
/// assert!(RelativePath::new("../..").is_normalized());
/// assert!(RelativePath::new("../../foo/bar/baz.txt").is_normalized());
///
/// // These are not normalized.
/// assert!(!RelativePath::new(".").is_normalized());
/// assert!(!RelativePath::new("./baz.txt").is_normalized());
/// assert!(!RelativePath::new("foo/..").is_normalized());
/// assert!(!RelativePath::new("foo/../baz.txt").is_normalized());
/// assert!(!RelativePath::new("foo/.").is_normalized());
/// assert!(!RelativePath::new("foo/./baz.txt").is_normalized());
/// assert!(!RelativePath::new("../foo/./bar/../baz.txt").is_normalized());
/// ```
#[must_use]
pub fn is_normalized(&self) -> bool {
self.components()
.skip_while(|c| matches!(c, Component::ParentDir))
.all(|c| matches!(c, Component::Normal(_)))
}
/// Creates an owned [`RelativePathBuf`] like `self` but with the given file
/// name.
///
/// See [`set_file_name`] for more details.
///
/// [`set_file_name`]: RelativePathBuf::set_file_name
///
/// # Examples
///
/// ```
/// use relative_path::{RelativePath, RelativePathBuf};
///
/// let path = RelativePath::new("tmp/foo.txt");
/// assert_eq!(path.with_file_name("bar.txt"), RelativePathBuf::from("tmp/bar.txt"));
///
/// let path = RelativePath::new("tmp");
/// assert_eq!(path.with_file_name("var"), RelativePathBuf::from("var"));
/// ```
pub fn with_file_name<S: AsRef<str>>(&self, file_name: S) -> RelativePathBuf {
let mut buf = self.to_relative_path_buf();
buf.set_file_name(file_name);
buf
}
/// Extracts the stem (non-extension) portion of [`file_name`][Self::file_name].
///
/// The stem is:
///
/// * [`None`], if there is no file name;
/// * The entire file name if there is no embedded `.`;
/// * The entire file name if the file name begins with `.` and has no other `.`s within;
/// * Otherwise, the portion of the file name before the final `.`
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path = RelativePath::new("foo.rs");
///
/// assert_eq!("foo", path.file_stem().unwrap());
/// ```
pub fn file_stem(&self) -> Option<&str> {
self.file_name()
.map(split_file_at_dot)
.and_then(|(before, after)| before.or(after))
}
/// Extracts the extension of [`file_name`][Self::file_name], if possible.
///
/// The extension is:
///
/// * [`None`], if there is no file name;
/// * [`None`], if there is no embedded `.`;
/// * [`None`], if the file name begins with `.` and has no other `.`s within;
/// * Otherwise, the portion of the file name after the final `.`
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// assert_eq!(Some("rs"), RelativePath::new("foo.rs").extension());
/// assert_eq!(None, RelativePath::new(".rs").extension());
/// assert_eq!(Some("rs"), RelativePath::new("foo.rs/.").extension());
/// ```
pub fn extension(&self) -> Option<&str> {
self.file_name()
.map(split_file_at_dot)
.and_then(|(before, after)| before.and(after))
}
/// Creates an owned [`RelativePathBuf`] like `self` but with the given
/// extension.
///
/// See [`set_extension`] for more details.
///
/// [`set_extension`]: RelativePathBuf::set_extension
///
/// # Examples
///
/// ```
/// use relative_path::{RelativePath, RelativePathBuf};
///
/// let path = RelativePath::new("foo.rs");
/// assert_eq!(path.with_extension("txt"), RelativePathBuf::from("foo.txt"));
/// ```
pub fn with_extension<S: AsRef<str>>(&self, extension: S) -> RelativePathBuf {
let mut buf = self.to_relative_path_buf();
buf.set_extension(extension);
buf
}
/// Build an owned [`RelativePathBuf`], joined with the given path and
/// normalized.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// assert_eq!(
/// RelativePath::new("foo/baz.txt"),
/// RelativePath::new("foo/bar").join_normalized("../baz.txt").as_relative_path()
/// );
///
/// assert_eq!(
/// RelativePath::new("../foo/baz.txt"),
/// RelativePath::new("../foo/bar").join_normalized("../baz.txt").as_relative_path()
/// );
/// ```
pub fn join_normalized<P>(&self, path: P) -> RelativePathBuf
where
P: AsRef<RelativePath>,
{
let mut buf = RelativePathBuf::new();
relative_traversal(&mut buf, self.components());
relative_traversal(&mut buf, path.as_ref().components());
buf
}
/// Return an owned [`RelativePathBuf`], with all non-normal components
/// moved to the beginning of the path.
///
/// This permits for a normalized representation of different relative
/// components.
///
/// Normalization is a _destructive_ operation if the path references an
/// actual filesystem path. An example of this is symlinks under unix, a
/// path like `foo/../bar` might reference a different location other than
/// `./bar`.
///
/// Normalization is a logical operation and does not guarantee that the
/// constructed path corresponds to what the filesystem would do. On Linux
/// for example symbolic links could mean that the logical path doesn't
/// correspond to the filesystem path.
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// assert_eq!(
/// "../foo/baz.txt",
/// RelativePath::new("../foo/./bar/../baz.txt").normalize()
/// );
///
/// assert_eq!(
/// "",
/// RelativePath::new(".").normalize()
/// );
/// ```
#[must_use]
pub fn normalize(&self) -> RelativePathBuf {
let mut buf = RelativePathBuf::with_capacity(self.inner.len());
relative_traversal(&mut buf, self.components());
buf
}
/// Constructs a relative path from the current path, to `path`.
///
/// This function will return the empty [`RelativePath`] `""` if this source
/// contains unnamed components like `..` that would have to be traversed to
/// reach the destination `path`. This is necessary since we have no way of
/// knowing what the names of those components are when we're building the
/// new relative path.
///
/// ```
/// use relative_path::RelativePath;
///
/// // Here we don't know what directories `../..` refers to, so there's no
/// // way to construct a path back to `bar` in the current directory from
/// // `../..`.
/// let from = RelativePath::new("../../foo/relative-path");
/// let to = RelativePath::new("bar");
/// assert_eq!("", from.relative(to));
/// ```
///
/// One exception to this is when two paths contains a common prefix at
/// which point there's no need to know what the names of those unnamed
/// components are.
///
/// ```
/// use relative_path::RelativePath;
///
/// let from = RelativePath::new("../../foo/bar");
/// let to = RelativePath::new("../../foo/baz");
///
/// assert_eq!("../baz", from.relative(to));
///
/// let from = RelativePath::new("../a/../../foo/bar");
/// let to = RelativePath::new("../../foo/baz");
///
/// assert_eq!("../baz", from.relative(to));
/// ```
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// assert_eq!(
/// "../../e/f",
/// RelativePath::new("a/b/c/d").relative(RelativePath::new("a/b/e/f"))
/// );
///
/// assert_eq!(
/// "../bbb",
/// RelativePath::new("a/../aaa").relative(RelativePath::new("b/../bbb"))
/// );
///
/// let a = RelativePath::new("git/relative-path");
/// let b = RelativePath::new("git");
/// assert_eq!("relative-path", b.relative(a));
/// assert_eq!("..", a.relative(b));
///
/// let a = RelativePath::new("foo/bar/bap/foo.h");
/// let b = RelativePath::new("../arch/foo.h");
/// assert_eq!("../../../../../arch/foo.h", a.relative(b));
/// assert_eq!("", b.relative(a));
/// ```
pub fn relative<P>(&self, path: P) -> RelativePathBuf
where
P: AsRef<RelativePath>,
{
let mut from = RelativePathBuf::with_capacity(self.inner.len());
let mut to = RelativePathBuf::with_capacity(path.as_ref().inner.len());
relative_traversal(&mut from, self.components());
relative_traversal(&mut to, path.as_ref().components());
let mut it_from = from.components();
let mut it_to = to.components();
// Strip a common prefixes - if any.
let (lead_from, lead_to) = loop {
match (it_from.next(), it_to.next()) {
(Some(f), Some(t)) if f == t => continue,
(f, t) => {
break (f, t);
}
}
};
// Special case: The path we are traversing from can't contain unnamed
// components. A relative path might be any path, like `/`, or
// `/foo/bar/baz`, and these components cannot be named in the relative
// traversal.
//
// Also note that `relative_traversal` guarantees that all ParentDir
// components are at the head of the path being built.
if lead_from == Some(Component::ParentDir) {
return RelativePathBuf::new();
}
let head = lead_from.into_iter().chain(it_from);
let tail = lead_to.into_iter().chain(it_to);
let mut buf = RelativePathBuf::with_capacity(usize::max(from.inner.len(), to.inner.len()));
for c in head.map(|_| Component::ParentDir).chain(tail) {
buf.push(c.as_str());
}
buf
}
/// Check if path starts with a path separator.
#[inline]
fn starts_with_sep(&self) -> bool {
self.inner.starts_with(SEP)
}
/// Check if path ends with a path separator.
#[inline]
fn ends_with_sep(&self) -> bool {
self.inner.ends_with(SEP)
}
}
impl<'a> IntoIterator for &'a RelativePath {
type IntoIter = Iter<'a>;
type Item = &'a str;
#[inline]
fn into_iter(self) -> Self::IntoIter {
self.iter()
}
}
/// Conversion from a [`Box<str>`] reference to a [`Box<RelativePath>`].
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path: Box<RelativePath> = Box::<str>::from("foo/bar").into();
/// assert_eq!(&*path, "foo/bar");
/// ```
impl From<Box<str>> for Box<RelativePath> {
#[inline]
fn from(boxed: Box<str>) -> Box<RelativePath> {
let rw = Box::into_raw(boxed) as *mut RelativePath;
unsafe { Box::from_raw(rw) }
}
}
/// Conversion from a [`str`] reference to a [`Box<RelativePath>`].
///
/// [`str`]: prim@str
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path: Box<RelativePath> = "foo/bar".into();
/// assert_eq!(&*path, "foo/bar");
///
/// let path: Box<RelativePath> = RelativePath::new("foo/bar").into();
/// assert_eq!(&*path, "foo/bar");
/// ```
impl<T> From<&T> for Box<RelativePath>
where
T: ?Sized + AsRef<str>,
{
#[inline]
fn from(path: &T) -> Box<RelativePath> {
Box::<RelativePath>::from(Box::<str>::from(path.as_ref()))
}
}
/// Conversion from [`RelativePathBuf`] to [`Box<RelativePath>`].
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use relative_path::{RelativePath, RelativePathBuf};
///
/// let path = RelativePathBuf::from("foo/bar");
/// let path: Box<RelativePath> = path.into();
/// assert_eq!(&*path, "foo/bar");
/// ```
impl From<RelativePathBuf> for Box<RelativePath> {
#[inline]
fn from(path: RelativePathBuf) -> Box<RelativePath> {
let boxed: Box<str> = path.inner.into();
let rw = Box::into_raw(boxed) as *mut RelativePath;
unsafe { Box::from_raw(rw) }
}
}
/// Clone implementation for [`Box<RelativePath>`].
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path: Box<RelativePath> = RelativePath::new("foo/bar").into();
/// let path2 = path.clone();
/// assert_eq!(&*path, &*path2);
/// ```
impl Clone for Box<RelativePath> {
#[inline]
fn clone(&self) -> Self {
self.to_relative_path_buf().into_boxed_relative_path()
}
}
/// Conversion from [`RelativePath`] to [`Arc<RelativePath>`].
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use relative_path::RelativePath;
///
/// let path: Arc<RelativePath> = RelativePath::new("foo/bar").into();
/// assert_eq!(&*path, "foo/bar");
/// ```
impl From<&RelativePath> for Arc<RelativePath> {
#[inline]
fn from(path: &RelativePath) -> Arc<RelativePath> {
let arc: Arc<str> = path.inner.into();
let rw = Arc::into_raw(arc) as *const RelativePath;
unsafe { Arc::from_raw(rw) }
}
}
/// Conversion from [`RelativePathBuf`] to [`Arc<RelativePath>`].
///
/// # Examples
///
/// ```
/// use std::sync::Arc;
/// use relative_path::{RelativePath, RelativePathBuf};
///
/// let path = RelativePathBuf::from("foo/bar");
/// let path: Arc<RelativePath> = path.into();
/// assert_eq!(&*path, "foo/bar");
/// ```
impl From<RelativePathBuf> for Arc<RelativePath> {
#[inline]
fn from(path: RelativePathBuf) -> Arc<RelativePath> {
let arc: Arc<str> = path.inner.into();
let rw = Arc::into_raw(arc) as *const RelativePath;
unsafe { Arc::from_raw(rw) }
}
}
/// Conversion from [`RelativePathBuf`] to [`Arc<RelativePath>`].
///
/// # Examples
///
/// ```
/// use std::rc::Rc;
/// use relative_path::RelativePath;
///
/// let path: Rc<RelativePath> = RelativePath::new("foo/bar").into();
/// assert_eq!(&*path, "foo/bar");
/// ```
impl From<&RelativePath> for Rc<RelativePath> {
#[inline]
fn from(path: &RelativePath) -> Rc<RelativePath> {
let rc: Rc<str> = path.inner.into();
let rw = Rc::into_raw(rc) as *const RelativePath;
unsafe { Rc::from_raw(rw) }
}
}
/// Conversion from [`RelativePathBuf`] to [`Rc<RelativePath>`].
///
/// # Examples
///
/// ```
/// use std::rc::Rc;
/// use relative_path::{RelativePath, RelativePathBuf};
///
/// let path = RelativePathBuf::from("foo/bar");
/// let path: Rc<RelativePath> = path.into();
/// assert_eq!(&*path, "foo/bar");
/// ```
impl From<RelativePathBuf> for Rc<RelativePath> {
#[inline]
fn from(path: RelativePathBuf) -> Rc<RelativePath> {
let rc: Rc<str> = path.inner.into();
let rw = Rc::into_raw(rc) as *const RelativePath;
unsafe { Rc::from_raw(rw) }
}
}
/// [`ToOwned`] implementation for [`RelativePath`].
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path = RelativePath::new("foo/bar").to_owned();
/// assert_eq!(path, "foo/bar");
/// ```
impl ToOwned for RelativePath {
type Owned = RelativePathBuf;
#[inline]
fn to_owned(&self) -> RelativePathBuf {
self.to_relative_path_buf()
}
}
impl fmt::Debug for RelativePath {
#[inline]
fn fmt(&self, fmt: &mut fmt::Formatter) -> fmt::Result {
write!(fmt, "{:?}", &self.inner)
}
}
/// [`AsRef<str>`] implementation for [`RelativePathBuf`].
///
/// # Examples
///
/// ```
/// use relative_path::RelativePathBuf;
///
/// let path = RelativePathBuf::from("foo/bar");
/// let string: &str = path.as_ref();
/// assert_eq!(string, "foo/bar");
/// ```
impl AsRef<str> for RelativePathBuf {
#[inline]
fn as_ref(&self) -> &str {
&self.inner
}
}
/// [`AsRef<RelativePath>`] implementation for [String].
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path: String = format!("foo/bar");
/// let path: &RelativePath = path.as_ref();
/// assert_eq!(path, "foo/bar");
/// ```
impl AsRef<RelativePath> for String {
#[inline]
fn as_ref(&self) -> &RelativePath {
RelativePath::new(self)
}
}
/// [`AsRef<RelativePath>`] implementation for [`str`].
///
/// [`str`]: prim@str
///
/// # Examples
///
/// ```
/// use relative_path::RelativePath;
///
/// let path: &RelativePath = "foo/bar".as_ref();
/// assert_eq!(path, RelativePath::new("foo/bar"));
/// ```
impl AsRef<RelativePath> for str {
#[inline]
fn as_ref(&self) -> &RelativePath {
RelativePath::new(self)
}
}
impl AsRef<RelativePath> for RelativePath {
#[inline]
fn as_ref(&self) -> &RelativePath {
self
}
}
impl cmp::PartialEq for RelativePath {
#[inline]
fn eq(&self, other: &RelativePath) -> bool {
self.components() == other.components()
}
}
impl cmp::Eq for RelativePath {}
impl cmp::PartialOrd for RelativePath {
#[inline]
fn partial_cmp(&self, other: &RelativePath) -> Option<cmp::Ordering> {
Some(self.cmp(other))
}
}
impl cmp::Ord for RelativePath {
#[inline]
fn cmp(&self, other: &RelativePath) -> cmp::Ordering {
self.components().cmp(other.components())
}
}
impl Hash for RelativePath {
#[inline]
fn hash<H: Hasher>(&self, h: &mut H) {
for c in self.components() {
c.hash(h);
}
}
}
impl fmt::Display for RelativePath {
#[inline]
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
fmt::Display::fmt(&self.inner, f)
}
}
impl fmt::Display for RelativePathBuf {
#[inline]
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
fmt::Display::fmt(&self.inner, f)
}
}
/// Helper struct for printing relative paths.
///
/// This is not strictly necessary in the same sense as it is for [`Display`],
/// because relative paths are guaranteed to be valid UTF-8. But the behavior is
/// preserved to simplify the transition between [`Path`] and [`RelativePath`].
///
/// [`Path`]: std::path::Path
/// [`Display`]: std::fmt::Display
pub struct Display<'a> {
path: &'a RelativePath,
}
impl<'a> fmt::Debug for Display<'a> {
#[inline]
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
fmt::Debug::fmt(&self.path, f)
}
}
impl<'a> fmt::Display for Display<'a> {
#[inline]
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
fmt::Display::fmt(&self.path, f)
}
}
/// [`serde::ser::Serialize`] implementation for [`RelativePathBuf`].
///
/// ```
/// use serde::Serialize;
/// use relative_path::RelativePathBuf;
///
/// #[derive(Serialize)]
/// struct Document {
/// path: RelativePathBuf,
/// }
/// ```
#[cfg(feature = "serde")]
impl serde::ser::Serialize for RelativePathBuf {
#[inline]
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: serde::ser::Serializer,
{
serializer.serialize_str(&self.inner)
}
}
/// [`serde::de::Deserialize`] implementation for [`RelativePathBuf`].
///
/// ```
/// use serde::Deserialize;
/// use relative_path::RelativePathBuf;
///
/// #[derive(Deserialize)]
/// struct Document {
/// path: RelativePathBuf,
/// }
/// ```
#[cfg(feature = "serde")]
impl<'de> serde::de::Deserialize<'de> for RelativePathBuf {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: serde::de::Deserializer<'de>,
{
struct Visitor;
impl<'de> serde::de::Visitor<'de> for Visitor {
type Value = RelativePathBuf;
#[inline]
fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
formatter.write_str("a relative path")
}
#[inline]
fn visit_string<E>(self, input: String) -> Result<Self::Value, E>
where
E: serde::de::Error,
{
Ok(RelativePathBuf::from(input))
}
#[inline]
fn visit_str<E>(self, input: &str) -> Result<Self::Value, E>
where
E: serde::de::Error,
{
Ok(RelativePathBuf::from(input.to_owned()))
}
}
deserializer.deserialize_str(Visitor)
}
}
/// [`serde::de::Deserialize`] implementation for [`Box<RelativePath>`].
///
/// ```
/// use serde::Deserialize;
/// use relative_path::RelativePath;
///
/// #[derive(Deserialize)]
/// struct Document {
/// path: Box<RelativePath>,
/// }
/// ```
#[cfg(feature = "serde")]
impl<'de> serde::de::Deserialize<'de> for Box<RelativePath> {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: serde::de::Deserializer<'de>,
{
struct Visitor;
impl<'de> serde::de::Visitor<'de> for Visitor {
type Value = Box<RelativePath>;
#[inline]
fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
formatter.write_str("a relative path")
}
#[inline]
fn visit_string<E>(self, input: String) -> Result<Self::Value, E>
where
E: serde::de::Error,
{
Ok(Box::<RelativePath>::from(input.into_boxed_str()))
}
#[inline]
fn visit_str<E>(self, input: &str) -> Result<Self::Value, E>
where
E: serde::de::Error,
{
Ok(Box::<RelativePath>::from(input))
}
}
deserializer.deserialize_str(Visitor)
}
}
/// [`serde::de::Deserialize`] implementation for a [`RelativePath`] reference.
///
/// ```
/// use serde::Deserialize;
/// use relative_path::RelativePath;
///
/// #[derive(Deserialize)]
/// struct Document<'a> {
/// #[serde(borrow)]
/// path: &'a RelativePath,
/// }
/// ```
#[cfg(feature = "serde")]
impl<'de: 'a, 'a> serde::de::Deserialize<'de> for &'a RelativePath {
fn deserialize<D>(deserializer: D) -> Result<Self, D::Error>
where
D: serde::de::Deserializer<'de>,
{
struct Visitor;
impl<'a> serde::de::Visitor<'a> for Visitor {
type Value = &'a RelativePath;
#[inline]
fn expecting(&self, formatter: &mut fmt::Formatter) -> fmt::Result {
formatter.write_str("a borrowed relative path")
}
#[inline]
fn visit_borrowed_str<E>(self, v: &'a str) -> Result<Self::Value, E>
where
E: serde::de::Error,
{
Ok(RelativePath::new(v))
}
#[inline]
fn visit_borrowed_bytes<E>(self, v: &'a [u8]) -> Result<Self::Value, E>
where
E: serde::de::Error,
{
let string = str::from_utf8(v).map_err(|_| {
serde::de::Error::invalid_value(serde::de::Unexpected::Bytes(v), &self)
})?;
Ok(RelativePath::new(string))
}
}
deserializer.deserialize_str(Visitor)
}
}
/// [`serde::ser::Serialize`] implementation for [`RelativePath`].
///
/// ```
/// use serde::Serialize;
/// use relative_path::RelativePath;
///
/// #[derive(Serialize)]
/// struct Document<'a> {
/// path: &'a RelativePath,
/// }
/// ```
#[cfg(feature = "serde")]
impl serde::ser::Serialize for RelativePath {
#[inline]
fn serialize<S>(&self, serializer: S) -> Result<S::Ok, S::Error>
where
S: serde::ser::Serializer,
{
serializer.serialize_str(&self.inner)
}
}
macro_rules! impl_cmp {
($lhs:ty, $rhs:ty) => {
impl<'a, 'b> PartialEq<$rhs> for $lhs {
#[inline]
fn eq(&self, other: &$rhs) -> bool {
<RelativePath as PartialEq>::eq(self, other)
}
}
impl<'a, 'b> PartialEq<$lhs> for $rhs {
#[inline]
fn eq(&self, other: &$lhs) -> bool {
<RelativePath as PartialEq>::eq(self, other)
}
}
impl<'a, 'b> PartialOrd<$rhs> for $lhs {
#[inline]
fn partial_cmp(&self, other: &$rhs) -> Option<cmp::Ordering> {
<RelativePath as PartialOrd>::partial_cmp(self, other)
}
}
impl<'a, 'b> PartialOrd<$lhs> for $rhs {
#[inline]
fn partial_cmp(&self, other: &$lhs) -> Option<cmp::Ordering> {
<RelativePath as PartialOrd>::partial_cmp(self, other)
}
}
};
}
impl_cmp!(RelativePathBuf, RelativePath);
impl_cmp!(RelativePathBuf, &'a RelativePath);
impl_cmp!(Cow<'a, RelativePath>, RelativePath);
impl_cmp!(Cow<'a, RelativePath>, &'b RelativePath);
impl_cmp!(Cow<'a, RelativePath>, RelativePathBuf);
macro_rules! impl_cmp_str {
($lhs:ty, $rhs:ty) => {
impl<'a, 'b> PartialEq<$rhs> for $lhs {
#[inline]
fn eq(&self, other: &$rhs) -> bool {
<RelativePath as PartialEq>::eq(self, other.as_ref())
}
}
impl<'a, 'b> PartialEq<$lhs> for $rhs {
#[inline]
fn eq(&self, other: &$lhs) -> bool {
<RelativePath as PartialEq>::eq(self.as_ref(), other)
}
}
impl<'a, 'b> PartialOrd<$rhs> for $lhs {
#[inline]
fn partial_cmp(&self, other: &$rhs) -> Option<cmp::Ordering> {
<RelativePath as PartialOrd>::partial_cmp(self, other.as_ref())
}
}
impl<'a, 'b> PartialOrd<$lhs> for $rhs {
#[inline]
fn partial_cmp(&self, other: &$lhs) -> Option<cmp::Ordering> {
<RelativePath as PartialOrd>::partial_cmp(self.as_ref(), other)
}
}
};
}
impl_cmp_str!(RelativePathBuf, str);
impl_cmp_str!(RelativePathBuf, &'a str);
impl_cmp_str!(RelativePathBuf, String);
impl_cmp_str!(RelativePath, str);
impl_cmp_str!(RelativePath, &'a str);
impl_cmp_str!(RelativePath, String);
impl_cmp_str!(&'a RelativePath, str);
impl_cmp_str!(&'a RelativePath, String);